Radial glia in the zebrafish brain: Functional, structural, and physiological comparison with the mammalian glia

Jurisch‐Yaksi, Nathalie; Yaksi, Emre; Kızıl, Çağhan

doi:10.1002/glia.23849

Cited by 119 publications

(114 citation statements)

References 315 publications

(479 reference statements)

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“…In this arrangement, youngest neurons are located closer to the neural progenitors of the habenula on the medial wall, while the oldest habenular neurons are located closer to the lateral wall. Similar sequential stacking of newly born neurons was also observed during forebrain development in both zebrafish (65,66) and rodents (6,67). Moreover, such a sequential order of neurogenesis contributes to different neural subtypes in the zebrafish hindbrain and spinal cord (8-10), as well as the rodent entorhinal cortex (5).…”

Section: (B)mentioning

confidence: 75%

Functional properties of habenular neurons are determined by developmental stage and sequential neurogenesis

et al. 2020

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The developing brain undergoes drastic alterations. Here, we investigated developmental changes in the habenula, a brain region that mediates behavioral flexibility during learning, social interactions, and aversive experiences. We showed that developing habenular circuits exhibit multiple alterations that lead to an increase in the structural and functional diversity of cell types, inputs, and functional modules. As the habenula develops, it sequentially transforms into a multisensory brain region that can process visual, olfactory, mechanosensory, and aversive stimuli. Moreover, we observed that the habenular neurons display spatiotemporally structured spontaneous activity that shows prominent alterations and refinement with age. These alterations in habenular activity are accompanied by sequential neurogenesis and the integration of distinct neural clusters across development. Last, we revealed that habenular neurons with distinct functional properties are born sequentially at distinct developmental time windows. Our results highlight a strong link between the functional properties of habenular neurons and their precise birthdate.

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Section: (B)mentioning

confidence: 75%

Functional properties of habenular neurons are determined by developmental stage and sequential neurogenesis

et al. 2020

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“…An interesting evolutionary aspect to stress is that astrocytes derived from RGCs in mouse express markers like GFAP, vimentin, glutamin synthase and S100β, which are also expressed by zebrafish RGCs ( März et al, 2010 ; Kroehne et al, 2011 ; Dimou and Gotz, 2014 ; Wang et al, 2019 ). The fact that the brain, in particular the telencephalon, of zebrafish is devoid of astrocytes, raises the question of which cells adopted their astrocytic functions [i.e., in blood brain barrier (BBB) establishment, neurotransmitter uptake, ionic regulation, and neurosteroidogenesis] ( Jurisch-Yaksi et al, 2020 ). More and more data in fish point to the general idea that zebrafish RGCs fulfill the functions of astrocytes.…”

Section: The Cellular and Molecular Morphology Of Nscs And The Absencmentioning

confidence: 99%

“…These data suggest the existence of heterogeneity between RGCs throughout the brain but also within the telencephalon ( Figure 2 ). In addition, a recent review documents the heterogeneity within the neural progenitor population in zebrafish with some progenitors expressing genes involved in astroglial functions and others expressing typical ependymal markers ( Jurisch-Yaksi et al, 2020 ). Also, among pallial RGCs, some seem to be deeply quiescent and others appear to constitute a self-renewing reservoir ( Than-Trong et al, 2020 ).…”

Section: Heterogeneity In the Rgc And Progenitor Populationmentioning

confidence: 99%

Common and Distinct Features of Adult Neurogenesis and Regeneration in the Telencephalon of Zebrafish and Mammals

et al. 2020

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In contrast to mammals, the adult zebrafish brain shows neurogenic activity in a multitude of niches present in almost all brain subdivisions. Irrespectively, constitutive neurogenesis in the adult zebrafish and mouse telencephalon share many similarities at the cellular and molecular level. However, upon injury during tissue repair, the situation is entirely different. In zebrafish, inflammation caused by traumatic brain injury or by induced neurodegeneration initiates specific and distinct neurogenic programs that, in combination with signaling pathways implicated in constitutive neurogenesis, quickly, and efficiently overcome the loss of neurons. In the mouse brain, injuryinduced inflammation promotes gliosis leading to glial scar formation and inhibition of regeneration. A better understanding of the regenerative mechanisms occurring in the zebrafish brain could help to develop new therapies to combat the debilitating consequences of brain injury, stroke, and neurodegeneration. The aim of this review is to compare the properties of neural progenitors and the signaling pathways, which control adult neurogenesis and regeneration in the zebrafish and mammalian telencephalon.

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“…In zebrafish, the main neurogenic niches that have been studied during adulthood are located in the telencephalon, the optic tectum and the cerebellum. The telencephalon remains undoubtedly the most investigated region of the brain, because it shares many features and homologies with the mammalian telencephalon, particularly considering adult neurogenesis (Kizil et al, 2012a;Diotel et al, 2020;Jurisch-Yaksi et al, 2020;Than-Trong et al, 2020). In the telencephalon, several studies have explored the identity and the diversity of the neural/progenitor cells sustaining the strong neurogenic activity observed in the different telencephalic subdomains (Pellegrini et al, 2007;Zupanc, 2008;März et al, 2010;Kizil et al, 2012a;Lindsey et al, 2012;Schmidt et al, 2014).…”

Section: Neural Stem Cells and Neural Progenitor Cells In The Adult Zmentioning

confidence: 99%

“…However, RGCs are suggested to sustain many astrocytic features and functions, such as typical marker expression, steroidogenesis, blood-brain barrier establishment and neurogenic properties (Diotel et al, 2018;Jurisch-Yaksi et al, 2020). Although, no astrogliosis was observed in zebrafish after telencephalic injury, reactive RGC gliosis occurs, as shown by the up-regulation of GFAP and vimentin as well as the hypertrophy of RGC glial processes (Kroehne et al, 2011).…”

Section: Glial Scar: a Paradigm For Understanding The Difference Betwmentioning

confidence: 99%

Cellular Mechanisms Participating in Brain Repair of Adult Zebrafish and Mammals After Injury

Ghaddar¹,

Lübke²,

Couret³

et al. 2020

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Adult neurogenesis is an evolutionary conserved process occurring in all vertebrates. However, striking differences are observed between the taxa, considering the number of neurogenic niches, the neural stem cell (NSC) identity and brain plasticity under constitutive and injury-induced conditions. Zebrafish has become a popular model for the investigation of the molecular and cellular mechanisms involved in adult neurogenesis. Compared to mammals, the adult zebrafish displays a high number of neurogenic niches distributed throughout the brain. Furthermore, it exhibits a strong regenerative capacity without scar formation or any obvious disabilities. In this review, we will first discuss the similarities and differences regarding (i) the distribution of neurogenic niches in the brain of adult zebrafish and mammals (mainly mouse) and (ii) the nature of the neural stem cells within the main telencephalic niches. In the second part, we will describe the cascade of cellular events occurring after telencephalic injury in zebrafish and mouse. Our study clearly shows that most early events happening right after the brain injury are shared between zebrafish and mouse including cell death, microglia and oligodendrocyte recruitment, as well as injury-induced neurogenesis. In mammals one of the consequences following an injury is the formation of a glial scar that is persistent. This is not the case in zebrafish, which may be one of the main reasons that zebrafish display a higher regenerative capacity.

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Radial glia in the zebrafish brain: Functional, structural, and physiological comparison with the mammalian glia

Cited by 119 publications

References 315 publications

Functional properties of habenular neurons are determined by developmental stage and sequential neurogenesis

Functional properties of habenular neurons are determined by developmental stage and sequential neurogenesis

Common and Distinct Features of Adult Neurogenesis and Regeneration in the Telencephalon of Zebrafish and Mammals

Cellular Mechanisms Participating in Brain Repair of Adult Zebrafish and Mammals After Injury

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